SE461927B - ROTATING DEPLACEMENT COMPRESSOR WITH DEVICE FOR REGULATION OF ITS INTERNAL VOLUME CONTAINER - Google Patents

Description

461 927 "2" These flow pulses generate disturbing noise and vibration that can damage the subsequent wiring system.

At the same time, the efficiency of the compressor deteriorates. For these reasons, one always strives for the built-in volume ratio to be adapted to the pressure in the pressure line.

In some cases, however, this pressure may vary, which makes it desirable to be able to vary the built-in volume ratio accordingly under such conditions. It is therefore since this, so-called We regulation. This is achieved in that the position of the edge of the outlet port which determines the opening moment can be varied, stepwise or continuously, whereby the volume of a working chamber at the opening moment changes and thus the built-in volume ratio. In this way it can be achieved that the pressure in said working chamber is substantially as great as the pressure in the pressure line.

Constructively, this can be realized in several ways, partly depending on the type of rotary displacement compressor in question. At e.g. a screw compressor with two cooperating rotors is a common control device designed as an axially movable slide arranged to be displaceable in a control parallel to the rotor shafts. The slide has a surface adjacent to the working space of the compressor which forms part of the jacket wall of the working space and connects to its shape. The slide is provided at the end facing the high pressure side of the compressor with an edge which forms an edge of the outlet port. When the position of said edge changes by displacing the slide, the moment of opening of a working chamber towards the outlet port and thus its volume at this moment changes.

For setting the slide in the correct position, where neither sub-e. =: Overcompression occurs, it is previously known to allow this to be affected depending on the known operating quantities of the compressor. '3' 461 927 Examples of such devices are described in SE-PS 427 063, SE-PS 430 709, DD-PS 127 878 and US-PS 3 936 239. The operating quantities sensed by the compressors described in said patent publications are either the power consumption of the drive motor or the difference between the outlet pressure and the pressure in a working chamber just before opening. In the former case, the control slide is adjusted so that the power consumption is minimized, which corresponds to a minimization of the efficiency loss due to under- or overcompression. In the second case, the pressure of the working chamber affects the slide to move in the direction of a larger outlet opening and the pressure of the pressure line the slide to move in the opposite direction, the slide adjusting to a position where equilibrium prevails between these two pressures.

However, both of these methods of controlling Vi regulation have significant shortcomings. source of error in that variations in the electricity supply network affect the sensed quantity. Furthermore, the power consumption as a function of deviations in the compressor final pressure from the pressure line pressure shows a very flat curve, which gives a poor precision, and the said influence from mains variations becomes relatively dominant. This way of controlling should therefore at most be sufficient to keep the efficiency losses somewhat down, but will not solve the noise problem.

The method of controlling the regulation with the help of the pressure difference has proved to be difficult to get to work. This is mainly due to the fact that the sensing of the final pressure in the compressor cannot be carried out in a reliable manner, since the sensed pressure fluctuates and considerable pressure surges occur every time a means defining a working chamber on a rotor passes the sensing point. Finding the equilibrium position in this way where neither under- nor over-compression occurs thus becomes practically impossible. The object of the present invention is therefore to provide a better method of controlling the setting of the built-in volume ratio.

This has been achieved according to the invention in that a rotary displacement compressor of the type initially indicated is provided with a connecting channel which communicates with its one end with the pressure line and with its other end with the working space in an area located near the compressor outlet port, said actuating means controlling, sensing means are constituted by a flow direction sensing arranged in the connecting channel. Advantageous embodiments of the invention are stated in the following subclaims.

Through the connecting channel, the working medium or a mixture thereof and oil can flow from the working space to the pressure line or vice versa. The direction of flow depends on which of the mouths of the duct the pressure is highest, it being the integrated average value of the respective pressure that is decisive.

The mouth in the pressure duct is exposed to a pressure which during a work cycle - corresponding to the time for a work chamber to move, a work chamber division in the transport direction - can be regarded as constant. At the mouth of the working chamber, on the other hand, the pressure fluctuates during the same period of time. The pressure is mainly within an interval between the final pressure in a working chamber and the pressure in the pressure line, but during a short period of time when a member delimiting a working chamber on a rotor passes the mouth of the duct, a very strong pressure surge is generated. However, the pressure surge is so short that it does not appreciably affect the mean pressure at this mouth and thus does not change the flow direction through the connecting channel.

Thanks to the fact that the flow direction in a connecting channel is used as the control quantity instead of the pressure difference, a control quantity is obtained in this way which is unaffected by the fluctuations in the pressure which occur during a working cycle at a point in the working space near the outlet. In particular, it applies to the mentioned powerful pressure shocks which make the conventional control via pressure sensing so problematic, since it is the instantaneous value of the pressure which constitutes the control variable.

Flow direction sensing provides a reliable and direct indication of whether under- or overcompression occurs and thus enables a more correct setting of the position of the movable outlet edge than when, as in the prior art, the power consumption of the drive motor or the pressure difference for this setting is sensed.

The invention therefore makes it possible to reduce to a greater extent than before noise and vibrations caused by under- or over-compression.

Figure 1 schematically shows a longitudinal section of a rotary displacement compressor of the screw rotor type provided with a device according to the invention, whereby insignificant details for the invention have been omitted.

Figure 2 shows a detail of figure 1.

The screw compressor shown in Figure 1 comprises two rotors (of which only one, 6 is shown in the figure) provided with helically extending lobes and grooves through which the rotors engage each other. The rotors are enclosed in a working space bounded by two end walls 2, 3, a fixed casing wall 1 and a movable slide 7. The surface of the slide 7 facing the working space has a shape which connects to the shape of the fixed casing wall 1 so that the working space in a cross section perpendicular against the rotor shafts is in the form of two intersecting circular cylinders. Gas is sucked in from a suction line 4 and compressed in V-shaped working chambers 461 927 formed between the rotors and the surrounding housing 1, 7 as these move axially from the suction line 4 to a pressure line 5, through which the compressed gas leaves a compress - sorn. The slide 7 has at its end located at the outlet port an edge 29 which forms part of the boundary line of the outlet port, and which determines the moment of a working chamber opening towards the outlet and thus the built-in volume ratio of the compressor. Optimal operating conditions are obtained when the built-in volume ratio corresponds to the pressure in the pressure line so that neither under- nor over-compression occurs. The position of the slide 7 and thus the position of the edge 29 is set by means of a valve-controlled hydraulic piston 15. a bore 8 through the slide 7, an axial groove 9 in the slide 7 on the side thereof facing away from the working space and a pipeline 10 connecting the groove 9 with the pressure line. The mouth 12 of the connecting channel 8, 9, 10 in the working space is located at a short distance from the opening moment determining the edge 29 on the slide 7, about 0.25 to 1, and preferably around 0.5 loodel- during a second phase, when the working chamber extends the lobe top passed the edge 29 of the outlet port 32, is open towards the outlet port 32, the gas being forced out through it. The pressure at this orifice 12 will then fluctuate mainly between the compressor final pressure and the pressure line pressure and result in an average pressure which is in this range. In addition, a short strong pressure surge occurs in the mouth 12 each time a lobe top passes the same, but it does not affect the average pressure significantly because it is so short-lived. The connecting channel 8, 9, 10 will be filled with a mixture of gas and oil from the oil film formed between the outer periphery of the rotors and the housing wall.

Through the connecting channel 8, 9, 10, the oil with gas bubbles can flow from the working space to the pressure line 5 or in the opposite direction depending on whether the average pressure at the mouth 12 in the working space is higher or lower than the pressure at the mouth 11 in the pressure line.

In the pipeline 10 a means 13 for sensing the direction of flow through it is arranged. If the final pressure in the compressor is less than the pressure in the pressure duct 5, i.e. in case of undercompression, the average pressure at the mouth 12 of the connecting duct 8, 9, 10 in the working space will be lower than the pressure at the mouth of the connecting duct 8, 9, 10 in the pressure line 5. The pressure difference will mean that the oil-gas mixture will flow through the connecting channel from the pressure line 5 to the working space, which is registered by the sensing means 13.

Figure 2 shows an advantageous embodiment of the sensing means 13. In the pipeline 10 a membrane 24 is clamped between two throttles 27, 28 provided with a central hole 30 which allows passage of the oil-gas mixture. When the oil-gas mixture in the conduit 10 is stationary, the diaphragm 24 occupies a neutral position, shown in solid lines in the figure. On the other hand, if it flows through the conduit 10, the membrane will bulge out in one direction or another depending on the flow direction. The figure shows in broken lines how the diaphragm 24 will adjust when the flow is directed upwards in the figure, representing a flow from the pressure line 5 to the working chamber. At a short distance from the membrane 24, a connector 25, 26 is arranged on each side. In the bulging position, the diaphragm 24 abuts against one of these connectors 25, 26. At the dashed position in the figure of the diaphragm 24, it abuts against the connector 25, a circuit 23a being closed for activating a drive means 22, for example a magnetic relay , to a valve 21 (see Figure 1). 461 927 In figure 1 the valve 21 is shown in a neutral position, corresponding to the neutral position of the diaphragm 24 in figure 2, whereby the position of the slide 7 is not affected. When the drive means 22 is activated by the signal from the connector 25, it causes the valve 21 to shift to the right in the figure so that pressure oil from a line 19 connected to a pressure oil source flows through the line 17 to the left side of the hydraulic cylinder 16 while allowing oil to leave the hydraulic cylinder 16 from its right side through the line 18 to a drain line 20. Thereby the piston 15 is displaced to the right in the figure and through the piston rod 14 also the slide 7 so that its edge 29 is moved to a position where the communication moment between a working chamber and the pressure line 5 is delayed. As the edge 29 is moved in this way, the built-in volume ratio of the compressor increases so that its final pressure increases, resulting in an increased average pressure at the mouth 12 of the connecting duct 8, 9, 10 in the working space. After a certain movement of the slide, the average pressure at the mouth 12 has approached the pressure in the pressure line so much that the flow through the obstruction channel 8, 9, 10 becomes so small that it is no longer able to hold the diaphragm 24 in contact with the connector 25. Then the signal is broken to the drive means 22 of the valve 21, whereby the valve 21 returns to the neutral position and the adjusting movement of the slide 7 ceases. The compressor now operates with a built-in volume ratio which essentially corresponds to the pressure in the pressure line 5.

If the sensing means 13 registers a direction of flow which is in the other direction, i.e. from the working chamber to the pressure line 5 there is overcompression. In this case, signal is given to the valve 21 to cause the slide to shift to the left in Figure 1 in a manner similar to that described above for undercompression.

It is not necessary that the control device is connected continuously, but it is sufficient if at regular intervals, e.g. every ten minutes switches it on.

"Q" 461 927 In the described example it has been stated that the setting movement is interrupted when the diaphragm 24 releases the contact with the connector 25, which occurs just before the flow through the connecting channel 8, 9, 10 has gone down to zero. Alternatively, the signal circuit 23 can be arranged so that the setting movement is interrupted only when the diaphragm 24 has passed its neutral position and abuts against the second connector 26. Then the flow through the connecting channel 8, 9, 10 has not only decreased to zero but also changed direction. In this case a certain overcompensation is obtained when adjusting the slide 7, while in the previously described case there was a certain undercompensation. However, the sensing device can be dimensioned so sensitive that this overcompensation or undercompensation becomes of little importance. The rule precision is in all conditions considerably better than with previously applied technology. The noise source that remains due to the final pressure in the compressor and the pressure in the pressure line 5 not being completely equalized is also counteracted by the open connection between the working space and the pressure line 5 through the connection channel 8, 9, 10.

It should be emphasized that the construction of the flow direction sensor 13 need not be limited to that described. It can e.g. be designed as a freely movable body between two connectors serving as a connector of the same contour as the channel and provided with a through hole or as a door pivotable between connectors. Furthermore, the setting of the Vi control means can be achieved as well by mechanical or electrical means as by hydraulic.

The connecting channel can alternatively be arranged entirely in the V¿ control means or completely outside it.

In the described example, the invention is applied to a compressor where the Vi control is performed with an axially arranged continuously displaceable slide. However, it can also be applied when the Vi control is achieved with a stepwise displaceable slide, with a radially movable slide, with lifting valves or in another way.

Claims (2)

._10- 461 927 BAIEEIKBAY A rotary displacement compressor comprising at least one rotor (6) arranged in a working space formed by a housing (1, 2, 3, 7) enclosing a rotor / rotors (6), in which a gaseous working medium is transported and compressed in working chambers from a suction line (4) connected inlet port (31) to an outlet port (32) connected to a pressure line (5), which outlet port (32) has an edge (29) which determines the opening moment towards the outlet port (32) of a working chamber and whose position is adjustable by means of actuating means (15, 16) controlled by sensing means (13), characterized in that the compressor is provided with a connecting channel (8, 9, 10), which communicates with one end (11) with the pressure line (5) and with its other end (12) with the working space in an area located near the outlet port (32) of the compressor and that said sensing means (13) controlling the actuating means is constituted by a flow direction sensing means (13) arranged in the connecting channel (8, 9, 10). for of sensing the flow direction in the connecting channel (8, 9, 10), said actuating means (15, 16) being arranged to displace said edge (29) in the direction of delaying said opening moment at a sensed flow in the connecting channel (8, 9, 10) in the direction from said one end (11) to said other end (12) and to displace said edge (29) in the direction of advancing said opening moment at a sensed flow in opposite direction. Compressor according to claim 1, characterized in that said rotor / rotors (6) are of the screw rotor type. Compressor according to claim 2, characterized in that the number of rotors (6) is two, the rotors (6) interfering with each other through helically extending grooves and running on the rotors (6) to form V-shaped working chamber- IEI. Compressor according to claim 3, characterized in that said edge (29) is formed by the end of an axially displaceable control slide (7) facing the outlet port (32).